DE10060344A1 - Method for regulating the output current and / or the output voltage of a switching power supply - Google Patents

Abstract

A switching circuit part (1) has a transformer (2), a control circuit (3) and an electronic switch (4). Inputs (X9,X10) connect to mains AC voltage. Outputs (LTG100,LTG101) supply an output voltage (Ua), one (LTG100) with a positive potential. A protective resistor (R10), two diodes (D10,D11) and a coil (L10) connect in series to a primary circuit (5) for the transformer. Two filter capacitors (C10,C11) are connected in parallel to the inputs. An Independent claim is also included for a circuit for implementing the method of the present invention.

Description

The invention relates to a method for regulating the output current and / or the voltage of a primarily controlled switching power supply with one Transformer and a voltage regulator, using a reference value which is formed internally in the circuit and to influence the voltage controller is used according to DE 100 18 229.1.

Switching power supplies based on the flux converter principle and free-swinging ones Flyback converters can limit the output current by limiting the primary current can be set in the transformer. This creates a current limitation that input and output voltage dependent and therefore not intended for everyone Use cases is applicable. The output voltage dependency can can be kept relatively small by suitable circuit dimensions, however requires an increased circuit complexity and thus causes additional costs. The input voltage dependency arises from the constant switch-off delay with voltage-dependent differences cher slope of the current and must be limited by additional wiring are, which also require an increased circuit complexity and thus cause additional costs. In addition, switching power supplies are without Known optocouplers, which usually have poor load regulation have and thus to a high output voltage at low Output current and to a low output voltage at a large Lead output current.

Switched-mode power supplies of the generic type are preferred for voltage supply supply of electrical or electronic devices with low supply voltage and are required in large numbers, so that a the most cost-effective circuit arrangement must be chosen, which one also eliminates the existing drawbacks.

The invention has for its object a method and a circuit to show which an almost load-independent voltage and / or Current control with relatively little circuitry allows.  

According to the invention to solve this problem is the setting of a constant duty cycle of the secondary current is provided, whereby the mean output current becomes proportional to the primary peak current. This will the output current is constant with a constant switch-off current. Through the Use of an internal reference value for influencing solution of the voltage regulator is also an almost load-independent Voltage control with few components enabled. For example it is possible to save the reference value at this time specify that at the time of storing the current in the converter is independent of the secondary burden. This results in Another advantage is that at low loads with a significantly low Ren clock frequency of the switched-mode power supply can be worked, whereby a very low idle input power is achieved. Furthermore, in such Circuitry dispenses with the use of an optocoupler so that considerable costs can be saved.

In an embodiment of the invention it is provided that the electronic switch for the primary current through the voltage regulator via a series resistor by an output signal that shortens compared to the output signal is controlled, which makes it possible to set the duty cycle becomes.

In an embodiment of the invention it is further provided that as Reference value the induced voltage of an auxiliary winding of the transformer is used, which gives the possibility of low voltage po potentials to work and thus a separation between the high and Low voltage side is unproblematic. In addition, the causes Manufacture of such transformers only low additional costs and leads to a considerable cost advantage over conventional circuit arrangements calculations. In a further embodiment it is provided that the reference worth at a fixed but variably adjustable time after an interruption of the primary circuit is cached.

In a further advantageous embodiment of the invention it is provided that the Reference value with an internal comparison value of the voltage regulator is compared and depending on the amount exceeded by the reference value is the time for renewed application of voltage to the Primary circle can be determined. Because of the amount of overshoot  in terms of circuitry when the voltage is applied to the Primary circuit is taken into account, the switching behavior of the switching network can be influenced in an advantageous manner, so that the cycle time is optimized can be. In a further embodiment of the invention, an optimization be carried out in such a way that a new voltage application supply of the primary circuit until a maximum current of the Transformer. Through these measures, depending on the stored reference value the duration of the switch-off time of the circuit breaker ters set, the switch-off time is longer, the higher the stored voltage was. After the switch-off time has elapsed, the power switch on until the current through the transformer preset maximum value is reached and a new cycle begins. As Circuit breaker a field effect transistor is usually used whereas, on the other hand, the storage by e.g. a sample and hold Element is done.

In an alternative embodiment of the invention, it is proposed that the current of the transformer is compared with a time-dependent reference value, the reference value being formed by

Reference (t _a) = Abschaltwelle / (1 + cut-off delay / _t)
(for t _a <minimum on time).

By comparing the reference value with the current of the transformer can thus compensate for the different rates of current rise ten are made so that when the rate of rise is high, the Shutdown is more likely to be initiated and thus a voltage independent Switch-off point is present. The particular advantage of this is that that an almost input voltage independent current limitation is possible, which are also integrated in a low-voltage IC can, since no connection to the higher voltage potential is necessary.

In a further embodiment of the invention is used to apply the above described method shows a circuit arrangement which is characterized in that the voltage regulator to supply it Control circuit can be used as a linear or switching regulator and that an auxiliary winding of the transformer a reference voltage for the  Voltage regulator supplies and that the primary circuit is an electronic switch having. In the circuit, the electronic switch takes on or off Shutdown of the voltage supply for the transformer and will by the voltage regulator, if necessary via a series resistor controlled, with a control via a shortened output signal he follows. The output signal is shortened to such an extent that the duty cycle of the Secondary current becomes constant. This will make the average output current proportional to the primary peak current. When the shutdown current is constant consequently the output current is also constant.

An auxiliary winding of the transformer supplies a reference voltage, which according to the invention at a fixed, adjustable time after an interruption of the primary circuit can be stored, whereby the advantage already mentioned almost load-independent output voltage. Another The voltage applied to the primary circuit can also be dependent of the extent to which the internal comparison value of the Voltage regulator done by the reference value, so that an influence on the cycle time and thus the clock rate can be made.

In a further embodiment of the invention, the circuitry provides that the primary circuit depending on the induced voltage of the auxiliary winding tion, preferably at a value <0.1 volts, can be switched on again.

In a further special embodiment of the invention, it is provided that the control voltage for the electronic switch is additionally proportional to the ratio by means of a voltage

is superimposed.

Alternatively, there is the option of the control voltage for the electronic Switch also superimposed by a voltage of the gate signal. It is particularly advantageous in such circuit arrangements that the primary supply voltage of the voltage regulator through the rectified te, regulated primary voltage and that on the secondary side no high Voltage potential is present. These measures are therefore none  additional protection requirements with regard to the higher voltage potenti than, for example by optocouplers etc., necessary on the secondary side.

The invention is explained below using a further circuit example. Fig. 1 shows a circuit diagram of a voltage regulator with a linear regulator to supply the control circuit wherein the switch is controlled via a truncated signal.

Fig. 1 shows a circuit diagram in a first embodiment of a switching power supply 11 which includes a transformer 12, a voltage regulator 13 and an electronic switch 14 and other circuit components. The mains AC voltage is connected to the inputs X9, X10, while the output voltage Ua is present at the outputs LTG100 and LTG101, namely the plus potential at the output LTG100. In the primary circuit 15 of the transformer 12 , a series resistor R10, two diodes D10, D11 and a coil L10 are connected in series, while two smoothing capacitors C10, C11 are connected in parallel to the inputs X9, X10 and the capacitor C10 on the one hand on the cathode of the Diode D11 or connected to inductor L10, while the second pole is connected to input X10. By contrast, the second capacitor C11 is connected directly in parallel to the secondary winding of the transformer 12 behind the inductor L10.

Secondary circuit 16 , on the other hand, has a diode D100 connected in series and a capacitor C100 connected in parallel with it. A capacitor C101 with a resistor R100 connected in parallel is connected on the one hand to the output LTG100 and on the other hand to the output LTG101. The rectified mains voltage is present at C11, while the rectified output voltage is present at C101.

The integrated circuit IC10 receives the supply voltage via the resistors R11 and R12. The connections GND, L and VDD also serve to supply the integrated circuit IC10 with a regulated operating voltage. The integrated circuit IC10 also contains a voltage regulator 13 , which is connected as a switching regulator. For operation as a linear controller, the outputs L and VDD are connected to one another, as shown in FIG. 1. The output G2 of the integrated circuit IC10 is connected via a series resistor R13 to the electronic switch 14 , a field effect transistor T10. The outputs L and VDD are further connected to the ground potential via a capacitor C13, while the input U is connected to the auxiliary winding Nh. The input is connected to the output of the field effect transistor T10, which in turn is connected to the ground potential via the resistor R14. In addition, a capacitor C14 is connected in series between the ground potential of the control part and the output LTG101. The input VT is connected to ground potential via a resistor R18

The function of the voltage regulation is as follows: The integrated circuit IC10 switches the output G2 to high, whereby the field effect transistor T10 is switched on. As a result, the current through the winding Np of the converter W10 increases, the same current also flowing through the resistor R14. When the switch-off threshold is reached at the connection IP of the integrated circuit IC10, connection G2 is switched to low and the field effect transistor T10 is thereby switched off. Due to the magnetic coupling of the three windings of transformer 2 , voltages are induced in all windings. A current of the following size initially flows through Nsek:

Isek = IP.Np/Nsec

Then the current drops to zero. Meanwhile, the voltage across Nsec is equal to the sum of the voltages across D100 and the output voltage. As long as the current is greater than zero, the voltages on the windings are in the same ratio to each other as the number of turns. This is used to regulate the output voltage. Because the magnetic coupling of the windings to one another is not ideal, a voltage overshoot occurs after switching off T10 before the voltage at Nh changes to the transmitted voltage

U (Nh) = U (Nsec) .Nh / Nsec

settles. For this reason, the peak value must not be used the voltage at Nh for voltage regulation at Nh can be evaluated. The Evaluation may only take place when the vibrations have subsided. in the Furthermore, the voltage drop at D100 is voltage-dependent, which means that Voltage at Nh is not constant during the current flow. In addition, must  the transistor or field effect transistor T10 are switched off longer than Current flows through Nsec, so none during part of the shutdown time Voltage more at Nh is available from the output voltage is dependent and can be evaluated. To solve the above problems will solve in each case in the control principle according to the invention fixed time interval after switching off G2 the voltage at U with a sample and hold element. This gives you one Measured value, which is largely independent of the coupling of the winding, because at the time of measurement the vibrations have already subsided. Besides, is ensures that the current through D100 is the same for each measurement and thus the voltage at D100 is the same. Now exceeds the measured value the internal reference value in IC10 is dependent on the amount of Exceeded the time until the next switching on of G2. ever the greater the overshoot, the longer the switch-off time. In one area The switch-off time varies from 0 to 10 ms from 4% of the reference voltage, so that the clock frequency to a minimum of 100 Hertz at low loads decreases and the output power drops to a few mW. A Base load of a few mW in the device is therefore sufficient to control the output voltage in a load range from nominal load (a few watts) to idle in Keep range of Unenn +/- 2%. After the switch-off period has elapsed, G2 set to high again, provided the energy stored in the converter is already there was completely transmitted to the secondary side, otherwise the Stromreg works as described below and a new cycle begins.

The function of the current control takes place in that after switching off T10 the output signal G2 remains switched off at least until the voltage at connection U of IC10 drops to <0.1 volt. This ensures that the energy stored in the converter is completely transmitted to the secondary side. If the converter W10 is constructed in such a way that the switch-on time of T10 at nominal load is much shorter than the switch-off time, this results in an output current limitation, which with a low output voltage, e.g. B. short circuit, is only slightly larger than at nominal output voltage. In order to improve the steepness of the current limitation, a voltage can be superimposed according to the voltage drop at R14, which is proportional to the ratio

(ON time (G) + OFF time (G)) / ON time (G)

is. This signal can be generated from the gate signal, for example.

A further possibility of realizing the current limitation independent of the output voltage is that the T10 is not controlled directly by the output signal G of the voltage regulator 14 , but by an output signal G2, which is shortened compared to G to such an extent that the duty cycle dsec of the secondary current becomes constant. This makes the average output current proportional to the primary peak current Ip. With a constant switch-off current Ip, the output current Ia is also constant.

Ia = Ip.Np/Ns/2.dsek

Np = primary number of turns
Ns = number of secondary turns

Since the AC voltage varies greatly, especially for devices that are in different countries, such as. B. in the USA with 110 volts and in Europe with 230 volts, the rate of rise of the current in Np is not constant. Due to the delay time between exceeding the reference at IP and switching off T10, different switch-off currents occur at different input voltages if a constant reference is used. To prevent this, a reference is used according to the invention, which increases according to the following formula:
reference voltage

(t _A) = cut-off threshold / 1 + Turn-Off / (t _a).

This ensures that the shutdown current is almost the input voltage is independent and the advantages according to the invention arise.  

LIST OF REFERENCE NUMBERS

1

Switching Power Supply

2

transformer

3

voltage regulators

4

electronic switch

5

primary circuit

6

secondary circuit
C10 smoothing capacitor
C11 smoothing capacitor
C13 capacitor
C14 capacitor
C15 capacitor
C100 capacitor
C101 capacitor
D10 diode
D11 diode
D12 diode
D100 diode
IC10 circuit
IP current in W10
L10 coil
L11 inductance
LTG100 output
LTG101 output
Nh auxiliary winding
Np winding (primary)
Ns winding (secondary)
R10 series resistor
R11 resistance
R12 resistance
R13 series resistor
R14 resistance
R15 resistance
R16 resistance
R17 resistance
R18 resistance
R100 resistance
T10 field effect transistor
U reference voltage
W10 converter
X9 input
X10 input

Claims (16)

1. A method for regulating the output current and / or the voltage of a primary-controlled switching power supply with a transformer ( 12 ) and a voltage regulator ( 13 ), a reference value being used which is formed internally in the circuit and is used to influence the voltage regulator ( 13 ) is according to DE 100 18 229.1, characterized by the setting of a constant duty cycle of the secondary current. 2. The method according to claim 1, characterized in that the electronic switch ( 14 ) for the primary current ( 15 ) through the voltage regulator ( 13 ) via a series resistor (R13) by an output signal (G2), which shortens the output signal (G) is controlled. 3. The method according to claim 1 or 2, characterized in that the induced voltage of an auxiliary winding (Nh) of the transformer ( 12 ) is used as a reference value. 4. The method according to claim 3, characterized in that the reference value is temporarily stored at a fixed, adjustable point in time after interruption of the primary circuit ( 15 ). 5. The method according to 1, 2, 3 or 4, characterized in that the reference value is compared with an internal comparison value of the voltage regulator ( 13 ) and, depending on the amount exceeded by the reference value, the time for renewed voltage application to the primary circuit ( 15 ) is determined. 6. The method according to one or more of claims 1 to 5, characterized in that the renewed voltage application to the primary circuit ( 15 ) takes place until a maximum current of the transformer ( 12 ) is reached. 7. The method according to one or more of claims 1 to 6, characterized in that the current of the transformer ( 12 ) is compared with a time-dependent reference value. 8. The method according to claim 7, characterized in that the value as the reference value
Reference (t _a) = cut-off threshold / (1 + cut-off delay / _t)
(for t _a <minimum on time)
is used. 9. Circuit for practicing the method according to one or more of claims 1 to 8, characterized in that the voltage regulator ( 13 ) is used to supply the control circuit as a linear or switching regulator and that an auxiliary winding (Nh) of the transformer ( 12 ) one Provides reference voltage (U) for the voltage regulator ( 13 ) and that the primary circuit ( 15 ) has an electronic switch ( 14 ). 10. The circuit according to claim 9, characterized in that the electronic switch ( 14 ) for the primary circuit ( 15 ) can be controlled by the voltage regulator ( 13 ) via a series resistor, with control being effected via a shortened output signal (G2). 11. Circuit according to claim 9 or 10, characterized in that the reference value for the induced voltage of the auxiliary winding (Nh) can be stored at a fixed, adjustable time after the primary circuit ( 15 ) has been interrupted. 12. Circuit according to claim 9, 10 or 11, characterized in that the voltage applied to the primary circuit ( 15 ) in dependence on the amount of the internal comparison value of the voltage regulator ( 13 ) is exceeded by the reference value. 13. Circuit according to claim 11, characterized in that the primary circuit ( 15 ) depending on the induced voltage of the auxiliary winding, preferably at a value of <0.1 volts, can be switched on again. 14. Circuit according to one or more of claims 9 to 13, characterized in that the control voltage for the switching regulator ( 14 ) additionally by a voltage proportional to the ratio
is superimposed. 15. Circuit according to one or more of claims 9 to 14, characterized in that the control voltage for the electronic switch ( 14 ) is additionally superimposed by a voltage of the gate signal. 16. Circuit according to one or more of claims 9 to 15, characterized in that the primary supply voltage of the voltage regulator ( 13 ) is effected by the rectified, regulated primary voltage and that no higher voltage potential is present secondarily.